ZENK expression in vocal nuclei is associated with singing behavior. Area X is an important nucleus for learning and stabilizing birdsong. ZENK expression is higher in Area X compared to that in other vocal nuclei when birds are singing. To reveal the relationship between the ZENK expression in Area X and song crystallization, immunohistochemistry was used to detect ZENK protein expression in Area X after the unilateral vocal nerve (tracheosyringeal nerve) section in adult male zebra finches. Sham operations had no effect on song. In contrast, section of unilateral vocal nerve could induce song decrystallization at the 7th day after the surgery. The spectral and the temporal features of birdsong were distorted more significantly in the right-side vocal nerve section than in the left-side vocal nerve section. In addition, after surgery, ZENK expression was higher in the right-side of Area X than in the left-side. These results indicate that the vocal nerve innervations probably are right-side dominant. ZENK expression in both sides of Area X decreased, as compared to control group after surgery, which suggests that the ZENK expression in Area X is related to birdsong crystallization, and that there is cooperation between the Area X in AFP and syrinx nerve.

成年雄性鸣禽的习得性发声信号——长鸣(long call)和鸣唱(song)是由前脑高级发声中枢启动, 以及由前脑最后一级 输出核团弓状皮质栎核(robust nucleus of the arcopallium, RA)整合输出。RA 投射神经元与位于中脑的基本发声中枢丘间 复合体背内侧核(dorsomedial nucleus of the intercollicular, DM)形成突触连接。该文采用电损毁与声谱分析相结合的方法, 通过依次损毁成年雄性斑胸草雀(Taeniopygia guttata)单侧RA 和DM 核团, 探讨了前脑和中脑对习得性发声的影响。 结果提示, RA 核团与DM 核团共同参与了对雄性斑胸草雀习得性声音的调控, 而且这种控制具有右侧优势。

The song of zebra finch is stable in life after it was learned successfully. Vocal plasticity is thought to be a motor exploration that can support continuous learning and optimization of performance. The activity of RA, an important pre-motor nucleus in songbird’s brain, influences the song directly. This variability in adult birdsong is associated with the activity of NMDA receptors in LMANRA synapses, but the detailed mechanism is unclear. The control of gain refers to modulation of a neuron’s responsiveness to input and is critically important for normal sensory, cognitive, and motor functions. Here, we observed the change of gain in RA projection neurons after exogenous NMDA was applied to activate NMDA receptors using the whole-cell current clamp recording. We found that NMDA substantially increased the slope (gain) of the firing rate-current relationship in RA projection neurons. The AMPA receptor-dependent excitability played a crucial role in the modulation of gain by NMDA. These results suggested that NMDA receptors may regulate the dynamics of RA projection neurons by input-output gain.

Objective Motor control is encoded by neuronal activity. Small conductance Ca2+-activated K+ channels (SK channels) maintain the regularity and precision of firing by contributing to the afterhyperpolarization (AHP) of the action potential in mammals. However, it is not clear how SK channels regulate the output of the vocal motor system in songbirds. The premotor robust nucleus of the arcopallium (RA) in the zebra finch is responsible for the output of song information. The temporal pattern of spike bursts in RA projection neurons is associated with the timing of the acoustic features of birdsong. Methods The firing properties of RA projection neurons were analyzed using patch clamp wholecell and cell-attached recording techniques. Results SK channel blockade by apamin decreased the AHP amplitude and increased the evoked firing rate in RA projection neurons. It also caused reductions in the regularity and precision of firing. RA projection neurons displayed regular spontaneous action potentials, while apamin caused irregular spontaneous firing but had no effect on the firing rate. In the absence of synaptic inputs, RA projection neurons still had spontaneous firing, and apamin had an evident effect on the firing rate, but caused no significant change in the firing regularity, compared with apamin application in the presence of synaptic inputs. Conclusion SK channels contribute to the maintenance of firing regularity in RA projection neurons which requires synaptic activity, and consequently ensures the precision of song encoding.

鸣禽是除了人类以外极少数具有发声信号学习能力的动物，其已成为研究运动序列控制和学习记忆神经过程的理想模型。鸣禽端脑中的高级发声中枢（high vocal center）、弓状皮质栎核（robust nucleus of the arcopallium）和脑干中的运动核团构成了控制发声的运动通路。该文对鸣禽端脑发声运动通路的电生理学特性及其在发声控制和鸣唱学习中的作用进行了全面的分析综述。